DE19827325A1 - Process for the electrochemical conversion of organic compounds using solid polymer electrolyte technology in an electrolysis liquid near the boiling point - Google Patents

Abstract

Process for the electrochemical conversion of organic substrates in an electrolytic cell, which is made up of DOLLAR A - a solid electrolyte, which consists of one or more superimposed layers of an ion exchange membrane and DOLLAR A - a cathode and an anode, which are in direct contact with the solid electrolyte, DOLLAR A using an electrolysis liquid, which is an essentially solution free of conductive salt, the electrolysis cell being operated at the boiling point of the electrolysis liquid or at a temperature up to 5 ° C. below its boiling point.

Description

The present invention relates to a process for the electrochemical oxidation or reduction of organic substrates, these reactions being carried out in an electrolysis cell which is composed of

• - A solid electrolyte consisting of one or more overlying layers of an ion exchanger membrane exists,
• - A cathode and an anode, which are connected to the solid-state electro lyten are in direct contact,

using an electrolysis liquid that is is an organic solution which is essentially free of conductive salt, where the electrolysis cell at the boiling point of Electrolysis liquid or a temperature up to 5 ° C below operates at its boiling point.

It is well known the solid polymer electrolyte Technology (SPE technology) (cf. "Ion exchange membranes in Electrolysis and Electroorganic Synthesis ", Dr.-Ing. Jakob Jörissen, Progress Reports VDI Row 3 No. 442; Dusseldorf: VDI Verlag 1996, Chapter 4) for electro-organic synthesis to use various organic compounds. At With this technology, an ion exchange membrane acts as a solid body electrolytes, so that electrolytic cells without conductive capable liquids can work. This principle enables electro-organic syntheses on permeable to the substrates Electrodes without the addition of conductive electrolytes. Specifically, z. B. describes the methoxylation of furan with methanol (loc. cit. Chapter 4.3.3). When using a largely water-free solution of methanol and furan as electrolysis liquid, however found that large cell voltages are required.

This process is compared to conventional electrolysis techniques advantageous because it yields particularly high yields can be achieved and a time-consuming work-up is unnecessary, since the use of conductive electrolytes is avoided can.  

However, the application of this technology is still affected significantly restricted that such electrolytic cells are not operated continuously over a longer period of time can be. The current density and thus the space-time-out To keep the prey constant, the cell voltage has to keep increasing increase. A relatively low cell voltage isn't just that desirable because it means low energy costs, the He Increase in cell voltage is also only up to a certain Limit value possible, without running the risk, the solid state electro irreversible damage. When this limit is reached therefore the reaction must be interrupted and the festival body electrolyte removed from the cell and processed or by a fresh one will be replaced.

It was therefore the task that according to the solid polymer Electrolyte technology working in the electrolyte technology To improve in terms of greater economy. In particular, a method is to be provided in which the current density remains constant over a longer period of time can be held without increasing the cell leads to tension.

Accordingly, the process defined at the outset was found.

The method according to the invention is basically suitable for electrochemical oxidation or reduction of all compounds, for which the SPE technology comes into consideration, the anodic Oxidations are preferred.

Such implementations are, for example

• - the anodic methoxylation of toluene derivatives
• - The anodic methoxylation of optionally N-alkylated C ₃ - to C ₁₀ -carboxamides
• - The anodic methoxylation of ethers
• the anodic dimerization of substituted benzenes, substituted toluenes and substituted or unsubstituted naphthalenes
• - The oxidation of aliphatic or alicyclic alcohols to aldehydes, ketones or carboxylic acids
• - The oxidation of aliphatic or alicyclic ethers Aldehydes, ketones or carboxylic acids

The process is particularly suitable for the preparation of methoxylated benzyl, benzal and benzoyl compounds of the general formula (I)

with the following meaning for R ¹ , A, B, m and n:
R ¹ : independently of one another hydrogen, C ₂ - to C ₄ -alkyl, C ₁ - to C ₄ -alkoxy or halogen
A: independently of one another methylene, carbonyl or -CH (OCH ₃ ) -
B: independently of one another H or O-CH ₃
m: a number from 0 to 3
n: a number from 1 to 3
wherein the compounds of general formula (I) have an oxidation number from 1 to 9, preferably from 1 to 5 and the oxidation numbers of the compounds of formula I are additive from the oxidation numbers of groups A and B, which correspond to their number in the formula (I) be taken into account, provided that
A = methylene the oxidation number 0,
A = -CH (OCH ₃ ) - oxidation number 1
A = carbonyl the oxidation number 2,
B = H the oxidation number 0
B = -OCH _{3 has} the oxidation number 1,
by electrochemical oxidation of compounds of the general formula II

in the

• the groups R ¹ , m and n have the same meaning as in formula I,
• - The groups X have the same meaning as the groups A in Have Formula I.
• - The groups Y have the same meaning as the groups B in Have Formula I.
• - however, the groups X and Y differ from the groups A and B of formula (I) are selected so that the Oxidation number of the compounds of the formula (II) is at least 1 less than that of the compounds of formula (I), the oxidation numbers of  Compounds of the formulas (II) and groups A and B analogously to which compounds of the formulas (I) and groups X and Y be calculated.

The process according to the invention is particularly suitable for the preparation of compounds of the general formula (I) with oxidation numbers from 1 to 9, preferably from 1 to 5. When calculating the oxidation numbers of the compounds of the general formula (I), the oxidation numbers of each group A and each Group B, which contain the compounds, added. Depending on the chemical structure of groups A and B, these groups are assigned a different numerical value.
A = methylene the oxidation number 0,
A = -CH (OCH ₃ ) - the oxidation number 1
A = carbonyl the oxidation number 2,
B = H the oxidation number 0
B = -OCH ₃ the oxidation number 1.

According to this calculation method, for example, benzaldehyde dimethyl acetal would have the oxidation number 2, since there is a group A, which is assigned the oxidation number 1 (-CH (OCH ₃ ) -) and a group B, which is also assigned the oxidation number 1 (-OCH ₃ ), contains. An aromatic nucleus, which carries 2 formyl groups in the form of their methyl acetal, has the corresponding oxidation number 4.

Compounds of the formula (I) in which R ^{1 is} hydrogen or methoxy and the group -AB together represent the dimethyl acetal of the formyl group can be prepared particularly easily. Those compounds are particularly preferred in which n = 1 and the group -AB is in para-position to a methoxy group. In the case of compounds in which n = 2, these two groups are preferably in the para position and the R ¹ is hydrogen. In those compounds in which n = 3, the groups -AB are in the 1, 3 and 5 positions on the aromatic nucleus and R ¹ is hydrogen.

In general, one starts from compounds in which the Group -X-Y represents methyl, so the oxidation number is 0.

However, it is also possible to use such compounds Formula (I) in which the oxidation number is higher than 0 is, in particular of methyl benzyl ether and the corresponding Derivatives. In this way, the method according to the invention  particularly economical for making connections with relatively high oxidation numbers can be used.

In general, in the process according to the invention, substances mixtures formed with different oxidation numbers. If in such cases products of formula (I) with a relative low oxidation number are not desired, it is possible these of those with the higher oxidation number by conventional Methods to separate, and the former again after the inventive method for producing the desired Use products. For example, it is possible to p-methoxytoluene (oxidation number 0) to produce a mixture that in addition to the mainly desired anisaldehyde dimethyl acetal (Oxidation number 2) or p-methoxybenzyl methyl ether (oxidation number 1) contains. After separating the two products, you can p-Methoxybenzylmethylether as the starting compound again Feed the electrolysis cell.

Furthermore, the method is particularly suitable for electro chemical methoxylation of methine, methylene or methyl groups of aliphatic or alicyclic mono- or diether preferably with 3 to 6 carbon atoms in the α-position an ether oxygen atom (starting ether) with formation of compounds in which at least one H atom of methine, Methylene or methyl groups of the starting ether through a Methoxy group is substituted.

Particularly suitable starting ethers are 1,2-dimethoxyethane, Tetrahydrofuran (THF), tetrahydropyran or 1,4-dioxane.

Electrolytic cells using a solid polymer electrolyte (SPE) work, are generally known (see. "Ion exchanger Membranes in electrolysis and electroorganic synthesis ", Dr.-Ing. Jakob Jörissen, Progress Reports VDI Series 3 No. 442; Düsseldorf: VDI Verlag 1996, Chapter 4).

Ion exchange membranes are particularly suitable for films processed polymers such as polyethylene, polyacrylates, polysulfone and perfluorinated polymers with negatively charged groups such as Carboxylate and sulfonate groups (cation exchange membranes) or positively charged groups like protonated or quaternized amino groups (anion exchange membranes).

Suitable cation exchange polymers are, for example, perfluorinated anionic polymers, preferably those of the general formula (III)

u = 5 to 13.5
w = 500 to 1500
v = 1, 2 or 3.

Such films are commercially available and, for example, among the Trade names Nafion®, (E.I. Du Pont de Nemours and Company) and Gore Select® (W.L. Gore & Associates, Inc.).

It has proven to be advantageous in part to use the solid electrolyte in the form of a gel swollen with an optionally N-alkylated C ₁ -C ₁₅ -carboxamide, which is obtainable by allowing the cation exchange membrane to swell in the carboxamide until the The resulting gel has 1.2 to 10 times the weight of the cation exchange membrane used. The increase in weight can be determined by weighing the membrane before swelling, immediately after removal from the swelling medium by dabbing with an absorbent fleece from the wetting liquid and immediately afterwards carrying out a differential weighing.

Swelling with N, N-dimethyl is particularly advantageously carried out formamide through. The swelling is expediently at a Temperature from 50 to 120 ° C carried out.

The solid electrolyte can be a single one Cation exchange membrane or around a layer of several, preferably act 2 to 10 membranes one above the other. The feast Body electrolyte conveniently has a thickness of 0.025 to 0.2 mm.

As anode or cathode materials with which the preferred entire surface of the solid electrolyte is in contact, come porous, electrically conductive materials, in particular Graphite felt sheets, carbon felt sheets, or textile materials, those at the contact surface with the solid electrolyte with carbon are covered.

The electrolysis liquid that is in contact with the electrode is generally a solution from the substrates, possibly the reaction products of the substrates and a solvent If the substrates during the definition operation  temperatures of the electrolytic cells, which are liquid, can affect the The use of solvents can be dispensed with.

Inert organic solvents and Suitable for water. Such organic solvents, which under practically no reaction to the process conditions for example optionally N-alkylated carboxamides with 1 to 15 Carbon atoms such as formamide, N-methylformamide, N, N, -dimethylformamide, Acetamides, N-methylpyrrolidone, pyrrolidone and benzamide, N-alkylated ureas with 3 to 15 carbon atoms such as N, N, N ', N'- Tetramethyl urea, ether, acetonitrile, benzonitrile, sulfolane, and esters such as methyl acetate. In general, the Proportion of water in the electrolysis liquid no more than 10, preferably 2 and very particularly preferably not more than 0.5 % By weight.

The electrolysis liquid contains essentially none of the lead electrolytes otherwise used in conventional cells such as acids, bases or electrolytes, d. that is, in generally less than 10, particularly preferably less than 1, very particularly preferably less than 0.1% by weight of this lead contains electrolytes.

Suitable electrolysis liquid in the preparation of the compounds of the general formula (I) is, above all, an organic solution containing

• 10 to 90% by weight of methanol,
• - 1 to 50 wt .-% compounds selected from a group of Compounds consisting of the compounds of formula I and II, the proportion of compounds of formula II in the Electrolysis liquid, based on the proportion of Compounds of this group, at least 1 mol%
• - 1 to 50 wt .-% of an optionally N-alkylated carboxamide with 1 to 15 carbon atoms or an N-alkylated urea with 3 up to 15 carbon atoms and
• - 0 to 30 wt .-% of another inert solvent.

The methoxylation of THF is advantageously carried out in bulk carried out, d. H. the electrolysis solution essentially contains only THF and methanol.  

The temperature of the electrolysis liquid is at the boiling point or up to 5, preferably up to 2 ° C below the boiling point.

A particularly favorable effect can be achieved if the Electrolysis liquid boils evenly in the cell. This will the temperature in the cell prefers as close to the Boiling point raised that the reaction mixture through the Heat development during the reaction only on the membrane surface comes to a boil. There is a certain amount of gas bubbles Development is absolutely desirable, but a violent boiling must be included strong gas bubble development can be avoided. The liquid in particular, should not boil so much that more than 5% of the Electrolysis cell are displaced by gas bubbles, otherwise the Mass transport to the membrane is no longer guaranteed and the Membrane is destroyed. This effect is sudden Voltage rise connected. A Zer caused by this The membrane can be reliably prevented by automatic voltage monitoring in the event of too high a voltage Voltage of electrical current through the cell is turned off.

The method according to the invention is expediently carried out in this way by making the electrolysis liquid parallel to the anode Solid electrolyte / anode interface preferably continuous flows through. Flow velocities are suitable Electrolysis liquid relative to the anode from 1 to 10 cm / s.

The current density is generally 0.1 to 40, preferably 1 to 10 A / dm ² . The voltages required to achieve these current densities are generally 2 to 20, preferably 3 to 10 volts. At higher voltages there is a risk of irreversible damage to the solid electrolyte.

Most are used in the electrochemical according to the invention Oxidation of organic substrates on the counter electrode (cathode) usually protons reduced to hydrogen.

The cells in which the procedure can be carried out are known and for example in loc. cit, chapter 4.2 and in the DE-A-195 33 773.

Suitable for practicing the process on an industrial scale especially those described in DE-A-195 33 773 serially switched plate stack cells.

These plate stack cells are in contact with each other standing layers aligned parallel to each other built, the layers consisting of the porous, electrical  conductive material and that from the solid electrolyte alternate. The basic structure of plate stack cells is for example from "Experiences with an Undivided Cell", Franz Wenisch et al., AIChE Symposium Series No 185, Vol. 75, pages 14 known until 18.

Experimental part

Table 1 shows the conditions under which examples and Comparative examples were carried out.

To experiment A

The experiment is divided into part 1, which reflects the state of the Technology represents (runtime up to 650h) and one subsequent part 2, which was carried out according to the invention (Runtime up to 650h). In part 1, when operating the electro chemical cell at 50 ° C, is a slow but steady Increase in cell voltage recognizable, that of 650 hours of operation duration (27 days) led to a cell voltage of over 16 volts In comparable previous attempts, such occurred Conditions some time after the specified operating time Destruction of the membrane.

According to the present invention, the temperature was raised to the boiling point of the liquid in the cell at 650 hours of operation (in this example, 68 ° C., see FIG. 1), and the cell voltage immediately dropped by about 5 volts. The decisive advantage for the technical application is above all that the cell voltage no longer showed a rising tendency.

To experiment B

Fig. 2 shows the application of the present invention, ie the operation of the SPE cells with boiling cell content, using eight examples (test parts B1 to B8) with changing operating conditions in terms of concentrations and current density (see Table 1). With the moderate conditions at the beginning of the term ( 1 and 2 ), an increase in voltage could be completely avoided. At 500 A / m ² current density ( 3 and 6 ), a relatively high value for electro-organic syntheses, the cell voltage was initially significantly higher, but with a clearly decreasing tendency. After 180 hours of operation, stable operation could be achieved at an increased level of the cell voltage, although damage to the cell components cannot be ruled out due to the current high current density ( 3 and 6 ). The conditions of Example 8 provided a particularly advantageous result with an acceptably high and, above all, stable cell voltage and a favorable current yield of the products: the current yield of the mainly desired double methoxylated product was high, and the moderate single-methoxylated product formed can , if it is not desired, can be returned after separation from the main product and further implemented.

Claims (7)

1. Process for the electrochemical conversion of organic substrates in an electrolysis cell, which is constructed from

• - A solid electrolyte consisting of one or more layers of an ion exchange membrane lying one above the other and
• a cathode and an anode which are in direct contact with the solid electrolyte,

using an electrolysis liquid, which is an essentially solution free of conductive salt, the electrolysis cell being operated at the boiling point of the electrolysis liquid or at a temperature up to 5 ° C. below its boiling point. 2. The method according to claim 1, characterized in that it is in the implementations

• - the anodic methoxylation of toluene derivatives
• - The anodic methoxylation of optionally N-alkylated C ₃ - to C ₁₀ -carboxamides
• - The anodic methoxylation of ethers
• - The anodic dimerization of substituted benzenes, substituted toluenes and substituted or unsubstituted naphthalenes
• - The oxidation of aliphatic or alicyclic Alko bring to aldehydes, ketones or carboxylic acids or
• - The oxidation of aliphatic or alicyclic ethers to aldehydes, ketones or carboxylic acids.

3. The method according to claim 1 or 2, characterized in that compounds of the general formula (I)
with the following meaning for R ¹ , A, B, m and n:
R ¹ : independently of one another hydrogen, C ₂ - to C ₄ -alkyl, C ₁ - to C ₄ -alkoxy or halogen
A: independently of one another methylene, carbonyl or -CH (OCH ₃ ) -
B: independently of one another H or O-CH ₃
m: a number from 0 to 3
n: a number from 1 to 3
wherein the compounds of the general formula (I) have an oxidation number from 1 to 5 and the oxidation numbers of the compounds of the formula I are additive from the oxidation numbers of the groups A and B, which are taken into account in accordance with their number in the formula (I) , put together with the proviso that
A = methylene the oxidation number 0,
A = -CH (OCH ₃ ) - the oxidation number 1
A = carbonyl the oxidation number 2,
B = H the oxidation number 0
B = -OCH ₃ the oxidation number 1
Has,
by electrochemical oxidation of compounds of the general formula II
in the

• the groups R ¹ , in and n have the same meaning as in formula I,
• - The groups X have the same meaning as the groups A in formula I.
• - The groups Y have the same meaning as the groups B in formula I.
• the groups X and Y, in contrast to the groups A and B of the formula (I), are selected such that the oxidation number of the compounds of the formula (II) is at least 1 lower than that of the compounds of the formula (I), the oxidation numbers of the compounds of the formulas (II) and groups X and Y being calculated analogously to those of the compounds of the formulas (I) and groups A and B,

manufactures, containing as electrolysis liquid a we essential lead electrolyte-free organic solution

• 10 to 90% by weight of methanol,
• 1 to 50% by weight of compounds selected from a group of compounds consisting of the compounds of the formulas I and II, the proportion of compounds of the formula II in the electrolysis liquid, based on the proportion of the compounds of this group, at least 1 Mol% is
• - 1 to 50 wt .-% of an optionally N-alkylated carboxamide with 1 to 15 carbon atoms or an N-alkylated urea with 3 to 15 carbon atoms and
• - 0 to 30 wt .-% of another inert solvent

starts. 4. The method according to claim 1 or 2, characterized in that to aliphatic or methine, methylene or methyl groups alicyclic mono- or diether which are in the α-position to a Stand ether oxygen atom, electrochemically methoxylated to form compounds in which at least one H atom of the methine, methylene or methyl groups of the outputs ther is substituted by a methoxy group 5. The method according to claims 1 to 4, characterized in net that the ion exchange membrane in the form of a gel lies. 6. The method according to claims 1 to 5, characterized in net that one perfluorinated anio as an ion exchange membrane uses niche polymers. 7. The method according to claims 1 to 6, characterized in that as electrodes graphite felt plates, carbon felt plates, or textile materials on the contact surface to the festival body electrolytes are covered with carbon.